Отправить статью по E-mail Studying the nature of the long-flying component of cosmic rays using X-ray emulsion chambers exposed in the Pamirs and Tien Shan
- Авторы: Borisov A.S.1, Chubenko A.P.1, Denisova V.G.1, Galkin V.I.2, Guseva Z.M.1, Kanevskaya E.A.1, Kogan M.G.1, Koulikov V.N.3, Morozov A.E.1, Mukhamedshin R.A.4, Nazarov S.N.2, Puchkov V.S.1, Pyatovsky S.E.1, Shoziyoev G.P.1, Smirnova M.D.1, Vargasov A.V.1
-
Учреждения:
- Lebedev Physical Institute
- Skobel’tsyn Institute of Nuclear Physics
- Central Research Institute of Machine Building (TsNIIMash)
- Institute for Nuclear Research
- Выпуск: Том 80, № 5 (2016)
- Страницы: 551-558
- Раздел: Proceedings of the XXII All-Russian Conference “Electromagnetic Fields and Materials” (Fundamental Physical Research)
- URL: https://journals.rcsi.science/1062-8738/article/view/184389
- DOI: https://doi.org/10.3103/S1062873816050038
- ID: 184389
Цитировать
Открытый доступ
Доступ предоставлен
Только для подписчиков
Аннотация
The origin of an excess of hadrons observed in deep homogeneous lead X-ray emulsion chambers (XRECs) at depths of more than 70 radiation length units is analyzed. Preliminary experimental data on the absorption of cosmic-ray hadrons in a two-storied XREC with a large air gap, exposed in the Tien Shan mountains, are presented. The chamber was designed to test the hypothesis that the main source of the excess of dark spots detected on X-ray films deep inside the XREC was substantial growth of the charmed-particle production cross section at energy Elab ∼ 75 TeV. The experimental data obtained using a two-storied REC and in experiments with deep homogeneous XRECs are compared to the results from calculations using the FANSY 1.0 model. The comparison shows qualitative agreement between the experimental and the model data, assuming high values of the charmed-particle production cross section when Elab ∼ 75 TeV in the forward kinematic region with xF ≥ 0.1.
Об авторах
A. Borisov
Lebedev Physical Institute
Автор, ответственный за переписку.
Email: borisov@sci.lebedev.ru
Россия, Moscow, 119991
A. Chubenko
Lebedev Physical Institute
Email: borisov@sci.lebedev.ru
Россия, Moscow, 119991
V. Denisova
Lebedev Physical Institute
Email: borisov@sci.lebedev.ru
Россия, Moscow, 119991
V. Galkin
Skobel’tsyn Institute of Nuclear Physics
Email: borisov@sci.lebedev.ru
Россия, Moscow, 119991
Z. Guseva
Lebedev Physical Institute
Email: borisov@sci.lebedev.ru
Россия, Moscow, 119991
E. Kanevskaya
Lebedev Physical Institute
Email: borisov@sci.lebedev.ru
Россия, Moscow, 119991
M. Kogan
Lebedev Physical Institute
Email: borisov@sci.lebedev.ru
Россия, Moscow, 119991
V. Koulikov
Central Research Institute of Machine Building (TsNIIMash)
Email: borisov@sci.lebedev.ru
Россия, Korolev, Moscow oblast, 141070
A. Morozov
Lebedev Physical Institute
Email: borisov@sci.lebedev.ru
Россия, Moscow, 119991
R. Mukhamedshin
Institute for Nuclear Research
Email: borisov@sci.lebedev.ru
Россия, Moscow, 117312
S. Nazarov
Skobel’tsyn Institute of Nuclear Physics
Email: borisov@sci.lebedev.ru
Россия, Moscow, 119991
V. Puchkov
Lebedev Physical Institute
Email: borisov@sci.lebedev.ru
Россия, Moscow, 119991
S. Pyatovsky
Lebedev Physical Institute
Email: borisov@sci.lebedev.ru
Россия, Moscow, 119991
G. Shoziyoev
Lebedev Physical Institute
Email: borisov@sci.lebedev.ru
Россия, Moscow, 119991
M. Smirnova
Lebedev Physical Institute
Email: borisov@sci.lebedev.ru
Россия, Moscow, 119991
A. Vargasov
Lebedev Physical Institute
Email: borisov@sci.lebedev.ru
Россия, Moscow, 119991
Дополнительные файлы
